Acetylaminofluorene and aminofluorene adducts inhibit in vitro transcription of a Xenopus 5S RNA gene only when located on the coding strand

DNA damage-induced ATM- and Rad-3-related (ATR) kinase activation in non-replicating cells is regulated by the XPB subunit of transcription factor IIH (TFIIH)

The role of the DNA damage response protein kinase ataxia telangiectasia-mutated (ATM)- and Rad-3-related (ATR) in the cellular response to DNA damage during the replicative phase of the cell cycle has been extensively studied. However, little is known about ATR kinase function in cells that are not actively replicating DNA and that constitute most cells in the human body. Using small-molecule inhibitors of ATR kinase and overexpression of a kinase-inactive form of the enzyme, I show here that ATR promotes cell death in non-replicating/non-cycling cultured human cells exposed to N-acetoxy-2-acetylaminofluorene (NA-AAF), which generates bulky DNA adducts that block RNA polymerase movement. Immunoblot analyses of soluble protein extracts revealed that ATR and other cellular proteins containing SQ motifs become rapidly and robustly phosphorylated in non-cycling cells exposed to NA-AAF in a manner largely dependent on ATR kinase activity but independent of the essential nucleotide excision repair factor XPA. Although the topoisomerase I inhibitor camptothecin also activated ATR in non-cycling cells, other transcription inhibitors that do not directly damage DNA failed to do so. Interestingly, genetic and pharmacological inhibition of the XPB subunit of transcription factor IIH prevented the accumulation of the single-stranded DNA binding protein replication protein A (RPA) on damaged chromatin and severely abrogated ATR signaling in response to NA-AAF and camptothecin. Together, these results reveal a previously unknown role for transcription factor IIH in ATR kinase activation in non-replicating, non-cycling cells.

ATR Kinase Inhibition Protects Non-cycling Cells from the Lethal Effects of DNA Damage and Transcription Stress

ATR (ataxia telangiectasia and Rad-3-related) is a protein kinase that maintains genome stability and halts cell cycle phase transitions in response to DNA lesions that block DNA polymerase movement. These DNA replication-associated features of ATR function have led to the emergence of ATR kinase inhibitors as potential adjuvants for DNA-damaging cancer chemotherapeutics. However, whether ATR affects the genotoxic stress response in non-replicating, non-cycling cells is currently unknown. We therefore used chemical inhibition of ATR kinase activity to examine the role of ATR in quiescent human cells. Although ATR inhibition had no obvious effects on the viability of non-cycling cells, inhibition of ATR partially protected non-replicating cells from the lethal effects of UV and UV mimetics. Analyses of various DNA damage response signaling pathways demonstrated that ATR inhibition reduced the activation of apoptotic signaling by these agents in non-cycling cells. The pro-apoptosis/cell death function of ATR is likely due to transcription stress because the lethal effects of compounds that block RNA polymerase movement were reduced in the presence of an ATR inhibitor. These results therefore suggest that whereas DNA polymerase stalling at DNA lesions activates ATR to protect cell viability and prevent apoptosis, the stalling of RNA polymerases instead activates ATR to induce an apoptotic form of cell death in non-cycling cells. These results have important implications regarding the use of ATR inhibitors in cancer chemotherapy regimens.

Transcription and DNA adducts: what happens when the message gets cut off?

DNA damage located within a gene's transcription unit can cause RNA polymerase to stall at the modified site, resulting in a truncated transcript, or progress past, producing full-length RNA. However, it is not immediately apparent why some lesions pose strong barriers to elongation while others do not. Studies using site-specifically damaged DNA templates have demonstrated that a wide range of lesions can impede the progress of elongating transcription complexes. The collected results of this work provide evidence for the idea that subtle structural elements can influence how an RNA polymerase behaves when it encounters a DNA adduct during elongation. These elements include: (1) the ability of the RNA polymerase active site to accommodate the damaged base; (2) the size and shape of the adduct, which includes the specific modified base; (3) the stereochemistry of the adduct; (4) the base incorporated into the growing transcript; and (5) the local DNA sequence.

Mechanisms of chromium-induced suppression of RNA synthesis in cellular and cell-free systems: relationship to RNA polymerase arrest

Chromium(VI) (Cr(VI)) can suppress both DNA replication and transcription as a result of chromium (Cr)-induced DNA damage. While progress has been made in the characterization of Cr-induced DNA polymerase arresting lesions, very little information is available on the inhibition of transcription by this metal. The aim of the present study was to identify the molecular mechanisms involved in the reduction of RNA synthesis by Cr. Following treatment with a moderately cytotoxic dose (approximately LC50) of Cr(VI) (150 microM for 2 h), total RNA synthesis was initially suppressed in CHO cells and recovered to control levels within 72 h post-treatment. In vitro nuclear run-on transcription assays of nuclei isolated from Cr(VI)-treated cells showed a similar amount of RNA synthesis suppression as observed in intact cells. Qualitative analysis of nascent transcripts revealed a general, concentration-dependent reduction in size suggesting that transcriptional elongation was inhibited following Cr-treatment. Transcriptional initiation in these nuclei was also reduced. To better determine whether transcriptional suppression was related to Cr-induced DNA damage we examined the transcriptional activity of T7 RNA polymerase on Cr(III)-treated plasmid DNA. Treatment of pGEM3Z-TS DNA with Cr(III) resulted in transcriptional arrest which occurred primarily at GC-rich and palindromic regions. However, in contrast to the cellular data, transcriptional initiation was unaffected in the in vitro transcription arrest assays. Taken together, these results suggest that the suppression of RNA synthesis by Cr is related to chromium-induced template DNA damage which prevents elongation leading to premature RNA polymerase arrest.

Binding of zinc finger protein transcription factor IIIA to its cognate DNA sequence with single UV photoproducts at specific sites and its effect on DNA repair

The relationship between DNA repair efficiency at specific locations in the binding site of the nine-zinc finger protein transcription factor IIIA (TFIIIA) and binding of its individual zinc fingers was studied. Homogeneously damaged oligonucleotides, which contained a single cis-syn cyclobutane thymine dimer (CTD) at one of six different sites in the internal control region (ICR) of the 5 S rRNA gene to generate a series of damaged DNA substrates, were prepared by chemical synthesis. Binding of TFIIIA to the substrates was assayed by measurement of dissociation constants (Kd), dissociation rates (koff), and protein-DNA contacts. The results indicated that a single CTD in the ICR does not significantly affect the Kd of TFIIIA. In contrast, CTDs at positions +55 and +72 (from the transcription start site) in the ICR markedly enhanced koff of TFIIIA from the complex. In addition, CTDs in these two sites increased methylation of the N7 of guanines (by dimethyl sulfate) in the zinc finger contacts of the ICR-TFIIIA complex. Furthermore CTDs at +55 and +72 were more efficiently removed from the complex than CTDs at other sites in the ICR by Xenopus oocyte nuclear extracts. This suggests that repair of CTDs closely correlates with changes in the binding of individual zinc fingers of the ICR-TFIIIA complex. These results have implications for the mechanism of DNA damage recognition and repair in protein-DNA complexes.

Lack of transcription-coupled repair of acetylaminofluorene DNA adducts in human fibroblasts contrasts their efficient inhibition of transcription

The N-(deoxyguanosine-8-yl)-2-acetylaminofluorene (dG-C8-AAF) lesion is among the most helix distorting DNA lesions. In normal fibroblasts dG-C8-AAF is repaired rapidly in transcriptionally active genes, but without strand specificity, indicating that repair of dG-C8-AAF by global genome repair (GGR) overrules transcription-coupled repair (TCR). Yet, dG-C8-AAF is a very potent inhibitor of transcription. The target size of inhibition (45 kilobases) suggests that transcription inhibition by dG-C8-AAF is caused by blockage of initiation rather than elongation. Cockayne's syndrome (CS) cells appear to be extremely sensitive to the cytotoxic effects of dG-C8-AAF and are unable to recover inhibited RNA synthesis. However, CS cells exhibit no detectable defect in repair of dG-C8-AAF in active genes, indicating that impaired TCR is not the cause of the enhanced sensitivity of CS cells. These and data reported previously suggest that the degree of DNA helix distortion determines the rate of GGR as well as the extent of inhibition of transcription initiation. An interchange of the transcription/repair factor TFIIH from promoter sites to sites of damage might underlie inhibition of transcription initiation. This process is likely to occur more rapidly and efficiently in the case of strongly DNA helix distorting lesions, resulting in a very efficient GGR, a poor contribution of TCR to repair of lesions in active genes, and an efficient inhibition of transcription.

Ultraviolet radiation-induced ubiquitination and proteasomal degradation of the large subunit of RNA polymerase II. Implications for transcription-coupled DNA repair

We have shown previously that UV radiation and other DNA-damaging agents induce the ubiquitination of a portion of the RNA polymerase II large subunit (Pol II LS). In the present study UV irradiation of repair-competent fibroblasts induced a transient reduction of the Pol II LS level; new protein synthesis restored Pol II LS to the base-line level within 16-24 h. In repair-deficient xeroderma pigmentosum cells, UV radiation-induced ubiquitination of Pol II LS was followed by a sustained reduction of Pol II LS level. In both normal and xeroderma pigmentosum cells, the ubiquitinated Pol II LS had a hyperphosphorylated COOH-terminal domain (CTD), which is characteristic of elongating Pol II. The portion of Pol II LS whose steady-state level diminished most quickly had a relatively hypophosphorylated CTD. The ubiquitinated residues did not map to the CTD. Importantly, UV-induced reduction of Pol II LS level in repair-competent or -deficient cells was inhibited by the proteasome inhibitors lactacystin or MG132. These data demonstrate that UV-induced ubiquitination of Pol II LS is followed by its degradation in the proteasome. These results suggest, contrary to a current model of transcription-coupled DNA repair, that elongating Pol II complexes which arrest at intragenic DNA lesions may be aborted rather than resuming elongation after repair takes place.

Processing of topoisomerase I cleavable complexes into DNA damage by transcription

Topoisomerase I (TOP1)-mediated DNA damage induced by camptothecin (CPT) in the presence of active transcription has been studied using purified calf thymus TOP1 and T7 RNA polymerase. CPT-stabilized TOP1 cleavable complexes located on the template strand within the transcribed region were found to be converted into irreversible strand breaks by the elongating RNA polymerase. By contrast, CPT-stabilized TOP1 cleavable complexes located on the non-template strand within the transcribed region was unaffected by the elongating RNA polymerase. Previous studies have demonstrated that the elongating T7 RNA polymerase is arrested by TOP1 cleavable complexes located on the template but not the non-template strand [Bendixen et al ., (1990) Biochemistry , 29, 5613-5619]. Together, these results suggest a model in which collision between the TOP1-cleavable complexes located on the template strand and the elongating RNA polymerase results in transcription arrest and conversion of TOP1 cleavable complexes into 'irreversible' strand breaks. The implication of the transcription collision model in DNA damage and repair, as well as cell killing, is discussed.

Transcription and DNA damage: a link to a kink

Living organisms are constantly exposed to a variety of naturally occurring and man-made chemical and physical agents that pose threats to health by causing cancer and other illnesses, as well as cell death. One mechanism by which these moieties can exert their toxic effects is by inducing modifications to the genome. Such changes in DNA often result in the formation of nucleotides not normally found in the double helix, bases containing covalent chemical alterations, single- and double-strand breaks, and interstrand and intrastrand cross-links. When these lesions are present during replication, mutations often result in the newly synthesized DNA. Likewise, when such damage occurs in a gene, transcription elongation, and hence expression, can be adversely affected because of pausing or arresting of the RNA polymerase at or near the altered site; this could result in the synthesis of a defective RNA molecule. It has become increasingly clear that transcription and DNA damage are intimately linked, since the removal of certain adducts from the genome is highly dependent on their location. When such lesions are present on the transcribed strand of actively expressed genetic loci, they are better cleared from that strand when compared to the complementary DNA or other quiescent regions. This process is called transcription-coupled DNA repair, and it modulates the mutagenic spectrum of many DNA-damaging agents. Furthermore, based upon evidence from systems in which it is absent, this process has a profound effect on ameliorating the adverse consequences of exposure to many environmentally relevant genotoxins. The precise cellular pathway that mediates the preferential clearance of DNA damage from active genetic loci has not yet been established, but it appears to be effected by a repertoire of proteins that are also involved in other DNA repair pathways and transcription as well as some factors that might be unique to it. Because a cellular process as indispensable as gene expression can be thwarted by the presence of DNA damage, an understanding of the mechanism underlying transcription-coupled DNA repair is relevant to the continued discernment of how environmental genotoxins endanger human health.

Effects of aminofluorene and acetylaminofluorene DNA adducts on transcriptional elongation by RNA polymerase II

A prominent model for the mechanism of transcription-coupled DNA repair proposes that an arrested RNA polymerase directs the nucleotide excision repair complex to the transcription-blocking lesion. The specific role for RNA polymerase II in this mechanism can be examined by comparing the extent of polymerase arrest with the extent of transcription-coupled repair for a specific DNA lesion. Previously we reported that a cyclobutane pyrimidine dimer that is repaired preferentially in transcribed genes is a strong block to transcript elongation by RNA pol II (Donahue, B.A., Yin, S., Taylor, J.-S., Reines, D., and Hanawalt, P. C. (1994) Proc. Natl. Acad. Sci. U. S. A. 91, 8502-8506). Here we report the extent of RNA polymerase II arrest by the C-8 guanine DNA adduct formed by N-2-aminofluorene, a lesion that does not appear to be preferentially repaired. Templates for an in vitro transcription assay were constructed with either an N-2-aminofluorene adduct or the helix-distorting N-2-acetylaminofluorene adduct situated at a specific site downstream from the major late promoter of adenovirus. Consistent with the model for transcription-coupled repair, an aminofluorene adduct located on the transcribed strand was a weak pause site for RNA polymerase II. An acetylaminofluorene adduct located on the transcribed strand was an absolute block to transcriptional elongation. Either adduct located on the nontranscribed strand enhanced polymerase arrest at a nearby sequence-specific pause site.

Lack of correlation between degree of interference with transcription and rate of strand specific repair in the HPRT gene of diploid human fibroblasts

The model that transcription-coupled excision repair reflects the interference of DNA damage with the transcription process predicts that the rate of such excision repair will be related to the degree to which a particular type of lesion blocks transcription. We tested this by measuring the rate of excision repair of guanine adducts formed in the HPRT gene of diploid human fibroblasts and in the overall genome by two structurally related polycyclic carcinogens, 1-nitrosopyrene (1-NOP) and N-acetoxy-2-acetylaminofluorene (N-AcO-AAF) and comparing the results with those we found previously using benzo[a]pyrene diol epoxide (BPDE). We also measured the degree of interference with in vitro transcription by these adducts. Our results showed that, although BPDE adducts are four times more effective than 1-NOP adducts in blocking transcription, the preferential and strand-specific repair of 1-NOP adducts was twice as fast as that of BPDE adducts. Excision repair of N-AcO-AAF adducts was significantly slower than that of BPDE adducts and was not strand-specific. The efficiency of blocking of transcription by deacetylated N-AcO-AAF adducts was similar to 1-NOP adducts. Therefore, the extent to which a particular lesion blocks transcription in vitro does not predict its rate of preferential or transcription-coupled excision repair.

Mechanisms of transcription-repair coupling and mutation frequency decline

Mutation frequency decline is the rapid and irreversible decline in the suppressor mutation frequency of Escherichia coli cells if the cells are kept in nongrowth media immediately following the mutagenic treatment. The gene mfd, which is necessary for mutation frequency decline, encodes a protein of 130 kDa which couples transcription to excision repair by binding to RNA polymerase and to UvrA, which is the damage recognition subunit of the excision repair enzyme. Although current evidence suggests that transcription-repair coupling is the cause of the preferential repair of the transcribed strand of mRNA encoding genes as well as of suppressor tRNA genes, the decline occurs under stringent response conditions in which the tRNA genes are not efficiently transcribed. Thus, the mechanism of strand-specific repair is well understood, but some questions remain regarding the precise mechanism of mutation frequency decline.

Effects of arabinosylcytosine-substituted DNA on DNA/RNA hybrid stability and transcription by T7 RNA polymerase

Cytosine arabinoside (araC) is a potent antileukemic agent which interferes with DNA replication both as a dNTP competitive inhibitor as well as after its misincorporation into DNA. We previously developed a chemical methodology for the synthesis of DNA oligomers containing araC which allowed us to study its site specific effects on duplex stability and chemical reactivity [Beardsley, G. P., Mikita, T., Klaus, M., & Nussbaum, A. (1988) Nucleic Acids Res. 16, 9165], as well as its effects on DNA ligase and DNA polymerase activity [Mikita, T., & Beardsley, G. P. (1988) Biochemistry 27, 4698]. The DNA polymerase studies, in addition to other observations, showed that araC in DNA templates could have an inhibitory effect on polymerase bypass. As a template lesion, there exists the potential for interference with other aspects of DNA metabolism, such as transcription. We have characterized a DNA/RNA hybrid containing an araC-G base pair, comparing thermal stability, chemical cleavage rates, and duplex gel mobility to an identically sequenced DNA duplex. We find that the A-form DNA/RNA hybrid and the B-form DNA duplex are nearly identical in the extent their thermal stability is affected by an araC-G(dG) base pair. Substitutions of araC for dC were made at various positions in a series of DNA duplex substrates containing a T7 RNA polymerase promoter with variable length coding strands. These were used to probe the effect of araC on promoter recognition, initiation, and elongation by T7 RNA polymerase in vitro. Substitutions in the central promoter region had no observable effect on RNA polymerase binding, initiation rate, or transcriptional output. Coding strand substitutions defined an area of high sensitivity in the initiation region where miss-starts, primer slippage, and an inability to escape from abortive cycling occur depending on the position substituted. Substitutions after position 10 had little effect on transcription output. These highly variable, position dependent effects indicate a narrow window of vulnerability where transcription output is severely reduced (approximately 100-fold) by a subtle DNA lesion that has little or no consequence when situated elsewhere in these small coding units.

Inhibition of plasmid reporter gene expression in CHO cells by DNA adducts of 2-amino-3-methylimidazo[4,5-f]quinoline and 2-amino-1-methyl-6-phenylimidazo[4,5-b]pyridine

2-Amino-3-methylimidazo[4,5-f]quinoline (IQ) and 2-amino-1-methyl-6-phenylimidazo[4,5-b]pyridine (PhIP) are two members of a family of carcinogenic heterocyclic amines (HAs) found in cooked meats that form DNA adducts after activation to N-acetoxy derivatives. The ability of IQ- and PhIP-DNA adducts to inhibit gene expression was investigated using a human growth hormone (hGH) reporter gene in a pUC12-based mammalian expression vector under the control of either the herpes simplex virus-1 thymidine kinase promoter or the human immunodeficiency virus-1 long terminal repeat. The plasmids were treated in vitro with 0, 5, 10, or 40 microM N-hydroxy-IQ or N-hydroxy-PhIP in the presence of a 10-fold molar excess of acetic anhydride to generate the N-acetoxy derivatives in situ. The adduct levels in the plasmids were quantitated by the 32P-postlabeling method. The adducted (and control) plasmids were each transfected into repair-deficient or -proficient Chinese hamster ovary cells, and expression of hGH was measured by immunoassay of growth hormone secreted into the cell medium. The results showed that IQ- and PhIP-DNA adducts inhibited gene expression in both plasmids and that the degree of inhibition of hGH production was proportional to the levels of IQ- and PhIP-DNA adducts. The degree of inhibition, however, was independent of the promoter, despite the differences in the strengths of the two promoters to drive hGH production. Repair capacity influenced the extent of inhibition of gene expression by HA adducts since, in general, fewer adducts were needed to inhibit reporter gene expression in repair-deficient cells than in repair-proficient cells. In both cell lines, DNA adducts of PhIP appeared to be more potent in inhibiting hGH expression than adducts of IQ. Whether alteration of gene expression by HA adducts plays a role in the carcinogenicity of these compounds deserves further study.

Site-specific benzo[a]pyrene diol epoxide-DNA adducts inhibit transcription elongation by bacteriophage T7 RNA polymerase

Benzo[a]pyrene, an extremely potent procarcinogen and mutagen, is metabolized to a variety of products, including the ultimate carcinogen 7,8-dihydroxy-9,10-epoxy- 7,8,9,10-tetrahydrobenzo[a]pyrene. This product of biotransformation reacts with DNA, forming a series of adducts principally at the N2 position of guanine that differ in their stereochemistry and exhibit unique biological properties. In order to gain a better understanding of the effects on RNA synthesis of these adducts, we used purified bacteriophage T7 RNA polymerase to transcribe a series of templates containing one of four stereoisomerically pure BPDE-guanine lesions--(+)-trans-,(-)-trans-,(+)-cis-anti-N2-BPDE-guanine--or no damaged bases. To construct suitable double-stranded oligodeoxynucleotides for these studies, we annealed an 11-mer containing a site-specific stereoisomerically pure N2-BPDE-guanine adduct, a 37-mer, and a 10-mer to a complementary 58-base sequence of single-stranded DNA. The oligomers were ligated, purified, and reannealed. The resulting DNA template contained the promoter for T7 RNA polymerase and a BPDE adduct at position +16 following the transcription initiation site. The results of the transcription assays clearly demonstrate that each of the adducts inhibits elongation by T7 RNA polymerase, but they do so to significantly different extents, depending on the stereochemical characteristics of the BPDE-modified guanine. The order of inhibition is (+)-trans > (-)-trans > (+)-cis > (-)-cis, when the amount of full-length transcript for each is compared to that obtained for an unmodified template. Furthermore, premature termination of RNA synthesis occurs at or near the site of the BPDE lesion as evidenced by the formation of discrete, truncated transcripts. These results might be related to the fact that the pyrenyl moiety of the trans-BPDE adducts is situated in the minor groove of double-stranded DNA, but is quasi-intercalated into the double helix in the case of the cis stereoisomers.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of abasic sites and DNA single-strand breaks on prokaryotic RNA polymerases

Abasic sites are thought to be the most frequently occurring cellular DNA damage and are generated spontaneously or as the result of chemical or radiation damage to DNA. In contrast to the wealth of information that exists on the effects of abasic sites on DNA polymerases, very little is known about how these lesions interact with RNA polymerases. An in vitro transcription system was used to determine the effects of abasic sites and single-strand breaks on transcriptional elongation. DNA templates were constructed containing single abasic sites or nicks placed at unique locations downstream from two different promoters and were transcribed by SP6 and Escherichia coli RNA polymerases. SP6 RNA polymerase is initially stalled at abasic sites with subsequent, efficient bypass of these lesions. E. coli RNA polymerase also bypassed abasic sites. In contrast, single-strand breaks introduced at abasic sites completely blocked the progression of both RNA polymerases. Sequence analysis of full-length transcripts revealed that SP6 and E. coli RNA polymerases insert primarily, if not exclusively, adenine residues opposite to abasic sites. This finding suggests that abasic sites may be highly mutagenic in vivo at the level of transcription.